JP2015215643A - Electronic equipment and recovery control method from power saving state - Google Patents

Abstract

PROBLEM TO BE SOLVED: To recover from a suspension mode in response to a remote wakeup request form a USB device even when a CPU incorporated in electronic equipment does not have any function corresponding to remote wakeup.SOLUTION: A USB controller 120 is configured to, when detecting a remote wakeup signal from a USB device 200, recover from a suspension mode (shift the status of the USB controller 120 itself to a normal mode). The USB controller 120 is configured to, when shifting the status, transmit a status signal to an MPU 150. The MPU 150 is configured to, when detecting that the status of the USB controller 120 is shifted from the transmitted status signal, transmit a recovery trigger signal to a CPU 110A. The CPU 110A is configured to recover from a suspend mode in accordance with a recovery trigger signal, and to allow the respective components of the USB control part 100A to recover from the suspend mode.

Description

  The present invention relates to an electronic device connected to a USB device and a return control method from a power saving state, and more specifically, based on a signal from a USB device when the electronic device is in a suspend mode (power saving state). The present invention relates to an electronic device that returns to a mode (normal power state) and a return control method from a power saving state.

USB (Universal Serial Bus) is a serial bus standard for connecting peripheral devices (USB devices) such as keyboards, mice, and digital cameras to electronic devices (USB hosts) such as computers and image forming apparatuses. And data communication between USB devices.
In addition to data communication, USB can supply power for driving USB devices from a USB host.

In power control for power saving between a USB host and a USB device, remote wakeup is known as a function related to power saving.
Here, the remote wakeup refers to inputting a remote wakeup signal indicating a remote wakeup request from the USB device to the USB host when the USB host is in the suspend mode, so that the USB host is in the suspend mode (power saving mode). Mode) to return to normal mode (normal power mode).

Generally, when a state in which communication between the USB host and the USB device is not performed (idle state) continues, the USB host shifts to a suspend mode in order to reduce power consumption. When the USB host shifts to the suspend mode, the power necessary for communication with the USB device is not supplied, so the USB device cannot communicate with the USB host.
Therefore, the USB device transmits a remote wakeup signal to the USB host in order to wake up the USB host (that is, return to the normal mode). When the USB host detects the remote wake-up signal, the USB host returns from the suspend mode and starts communication with the USB device.

As a USB host having such a remote wakeup function, there is known an image forming apparatus that controls whether or not to enter the suspend mode depending on the type of USB device connected to the USB connector (Patent Document 1).
In the image forming apparatus described in Patent Document 1, a remote wakeup signal transmitted from a USB device is detected by a built-in USB controller, and a CPU (Central Processing Unit) is notified that a remote wakeup event has occurred. Then, the CPU returns each component of the image forming apparatus from the suspend mode.

In the image forming apparatus described in Patent Document 1, a built-in CPU has a function corresponding to remote wakeup.
However, some electronic devices including the image forming apparatus may not have a function corresponding to the remote wakeup in the CPU. In that case, even if a remote wakeup signal is transmitted from the USB device and detected by the USB controller, the electronic device cannot return from the suspend mode.
In other words, conventionally, when an electronic device that is a USB host is in a suspended state, in order to return the electronic device from the suspend mode with a remote wake-up signal from the connected USB device, the built-in CPU must be remotely connected. It was necessary to have a function to cope with wakeup.

  The present invention has been made in view of the above-described conventional problems in an electronic device connected to a USB device. The object of the present invention is to provide a function corresponding to a remote wake-up request by a USB device in a CPU as in the past. It is to reduce the load on the CPU by avoiding the deterioration of the processing performance of the electronic device by giving it to other constituent elements.

  The present invention is an electronic device including a connection unit that connects a USB device, a USB controller that controls communication with the USB device, and a control unit that controls the USB controller, and the USB controller includes: A remote wakeup detection unit that detects a remote wakeup signal from the USB device; and when the remote wakeup signal is detected by the remote wakeup detection unit, the USB controller is switched from a power saving state to a normal power state. And a first state transition unit that transitions the power state from the power saving state to the normal power state based on a change in the power state of the USB controller. The present invention relates to an electronic device.

  According to the present invention, in an electronic device, a function corresponding to a remote wake-up request by a USB device is provided to other constituent elements than the CPU, thereby reducing the load on the CPU and avoiding a decrease in processing performance of the electronic device. be able to.

It is a block diagram of the USB control part of the electronic device which concerns on Embodiment 1 of this invention. It is a flowchart which shows the process sequence after the electronic device (USB control part) which concerns on Embodiment 1 of this invention transfers to a suspend mode, and returns to a normal mode. It is a block diagram of the USB control part of the electronic device which concerns on Embodiment 2 of this invention. It is a flowchart which shows the process sequence after the electronic device (USB control part) which concerns on Embodiment 2 of this invention transfers to a suspend mode, and returns to a normal mode. It is a flowchart which shows the process sequence after the electronic device (USB control part) which concerns on Embodiment 3 of this invention transfers to a suspend mode, and returns to a normal mode. It is a flowchart which shows the process sequence after the electronic device (USB control part) which concerns on Embodiment 4 of this invention transfers to a suspend mode, and returns to a normal mode.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block diagram of a USB control unit of an electronic device according to Embodiment 1 of the present invention.
The electronic device is, for example, an information processing apparatus or an image forming apparatus, and includes a USB control unit 100A here. A USB device 200 is connected to the USB control unit 100A with a USB cable 500 or the like.

  As shown in FIG. 1, a USB control unit (hereinafter simply referred to as a USB control unit) 100A of an electronic device mainly includes a CPU 110A, a USB controller 120, a USB connector A130, a USB connector B140, an MPU (Micro Processing Unit) 150, a RAM (Random Access Memory) 160 and the like.

The CPU 110A functions as a controller (control unit) of the USB control unit 100A and controls the USB control unit 100A.
Further, the CPU 110A has a state transition unit (corresponding to the second state transition unit in the present invention) that transitions the power state of the USB control unit 100A based on a trigger signal of the MPU 150 described later.

The USB controller 120 has a function of enabling connection of the USB device 200 and controls communication with the USB device 200 connected to the USB connector A 130 and the USB connector B 140.
When the remote wakeup signal is transmitted from the USB device 200, the USB controller 120 detects the remote wakeup signal and returns from the suspend mode. When returning from the suspend mode to the normal mode, the USB controller 120 transmits a status signal indicating the normal mode to the MPU 150.
As described above, when the USB controller 120 detects the remote wakeup signal, the USB controller 120 includes a state return unit that returns the power state of the USB controller 120 from the suspend mode to the normal mode.

  The USB connector A 130 and the USB connector B 140 are connectors having a USB interface function, and are used to connect the USB control unit 100 A and the USB device 200.

The MPU 150 is an auxiliary control unit of the USB control unit 100A, and monitors the state (for example, the normal mode, the suspend mode, etc.) of each component of the USB control unit 100A (specifically, for example, the USB control unit 100A). A status signal is received from each of the above components), and if necessary, a signal serving as a control trigger is transmitted to the CPU 110A to control the state of the USB control unit 100A.
For example, when the MPU 150 receives a status signal (indicating the normal mode) from the USB controller 120 that has detected the remote wake-up and detects that the state of the USB controller 120 has returned, the MPU 150 returns the CPU 110A from the suspend mode to the normal mode. Therefore, a return trigger signal is transmitted to the CPU 110A.

The RAM 160 is a storage device for temporarily storing data generated by each process of the CPU 110A.
In addition, the CPU 110A stores the work state (processing state) immediately before the transition in the RAM 160 before the transition to the suspend mode.

The USB device 200 is hardware compliant with the USB standard. In this embodiment, the short-range wireless communication module 300 is connected to the USB connector A130 with the USB cable 500, and the USB memory 400 is inserted into the USB connector B140. ing.
The USB device 200 may be any USB device 200 having a remote wakeup signal transmission function, and may be a mouse, a keyboard, a trackball, a tablet, a printer, a digital camera, or the like.
Further, in the description using the flowchart described later, the short-range wireless communication module 300 will be described as an example.

The USB cable 500 is made of a metal conductor such as a copper wire or a light conductor such as an optical fiber, and enables communication between the USB control unit 100A and the USB device 200.
In the present embodiment, the USB control unit 100A and the USB device 200 are connected by wire as the USB cable 500, but can also be connected and communicated using wireless (Wireless USB).

FIG. 2 is a flowchart showing a processing procedure from when the USB control unit 100A based on the block configuration of FIG. 1 shifts to the suspend mode until it returns to the normal mode.
When the power source of the USB control unit 100A is turned on (S101), the CPU 110A confirms whether there is a suspend transition notification from the MPU 150 (S102).
That is, the CPU 110A waits for a suspend transition notification (No in S102), and when the suspend transition notification is made to the CPU 110A (when the CPU 110A confirms the suspend transition notification) (S102 Yes), the CPU 110A includes the USB controller 120 and the near field wireless communication. The communication module 300 is commanded (controlled) to shift to the suspend mode (S103).

  When the USB controller 120 and the short-range wireless communication module 300 shift to the suspend mode according to the suspend mode transition command (S103) of the CPU 110A (S104), the CPU 110A stores the current processing state (setting) of the USB control unit 100A in the RAM 160. Save and shift to suspend mode (STR: Suspend to RAM) (S105).

After the USB control unit 100A shifts to the suspend mode, if the short-range wireless communication module 300 is accessed from, for example, an IC card or a smartphone, the short-range wireless communication module 300 sends a remote wakeup event to the USB control unit 100A. Issue (ie, send a remote wakeup signal).
When the USB controller 120 detects the remote wake-up signal transmitted to the USB control unit 100A by the short-range wireless communication module 300 (S106 Yes), the USB controller 120 returns from the suspend mode to the normal mode and transmits a status signal to the MPU 150 (S107). ).

  When the MPU 150 receives the status signal from the USB controller 120 and detects that the state of the USB controller 120 has changed, the MPU 150 triggers the CPU 110A to return the state of the USB control unit 100A from the suspend mode to the normal mode. A signal is transmitted (S108).

When the CPU 110A receives the return trigger signal from the MPU 150, the CPU 110A returns from the suspend mode to the normal mode (S109).
When the CPU 110A returns to the normal mode (S109), the CPU 110A returns each component of the USB control unit 100A from the suspend mode and resumes (reproduces the processing state saved immediately before shifting to the suspend mode) (S110).

When the CPU 110A restores each component of the USB control unit 100A (S110), the CPU 110A determines whether there is a response from the short-range wireless communication module 300 (S111).
When determining that there is a response from the short-range wireless communication module 300 (S111 Yes), the CPU 110A ends this process and continues the communication process with the short-range wireless communication module 300.
If the CPU 110A determines that there is no response from the short-range wireless communication module 300 (S111 No), the CPU 110A resets the short-range wireless communication module 300 and reconnects (S112).

(Embodiment 2)
FIG. 3 is a block diagram of the USB control unit of the electronic apparatus according to the second embodiment of the present invention.
In the second embodiment, an MPU 150 that monitors and manages the state of each component configuring the USB control unit (USB control unit 100A) of the electronic device according to the first embodiment is mounted on the CPU 110B.
Therefore, in the USB control unit (hereinafter, USB control unit 100B) of the electronic device according to the second embodiment, the USB controller 120 is connected to the CPU 110B only through the buffer 170 (without going through the MPU 150).
In FIG. 3, components having the same function (operation) as those in the first embodiment are denoted by the same reference numerals as those in FIG. 1.
Moreover, about CPU (110B), since MPU150 is provided inside, the code | symbol is changed from Embodiment 1. FIG. The CPU 110B includes a state transition unit (corresponding to the first state transition unit of the present invention) that transitions the power state of the USB control unit 100B based on a change in the power state of the USB controller 120.

FIG. 4 is a flowchart showing a processing procedure from when the USB control unit 100B based on the block configuration of FIG. 3 shifts to the suspend mode until it returns to the normal mode.
When the power source of the USB control unit 100B is turned on (S201) and then the USB control unit 100B enters an idle state, the CPU 110B determines whether or not the idle state continues for a predetermined time or more (S202).

  When the CPU 110B waits until the idle state of the USB control unit 100B continues for a predetermined time or longer (No in S202) and determines that the idle state continues for a predetermined time or longer (S202 Yes), the CPU 110B determines that the USB controller 120 And instructing (controlling) the short-range wireless communication module 300 to shift to the suspend mode (S203).

  In step S204, when the USB controller 120 and the short-range wireless communication module 300 shift to the suspend mode according to the suspend mode shift command (S203) of the CPU 110B (S204), the CPU 110B sets the current processing state (setting) of the USB control unit 100B. ) Is stored in the RAM 160, and the suspend mode is entered (S205).

After the USB control unit 100B shifts to the suspend mode, if the short-range wireless communication module 300 is accessed from, for example, an IC card or a smartphone, the short-range wireless communication module 300 sends a remote wakeup event to the USB control unit 100B. Issue (ie, send a remote wakeup signal).
When the USB controller 120 detects the remote wakeup signal transmitted to the USB control unit 100B by the short-range wireless communication module 300 (S206 Yes), the USB controller 120 returns from the suspend mode to the normal mode and transmits a status signal to the CPU 110B (S207). ).

When the CPU 110B receives the status signal from the USB controller 120 and detects that the state of the USB controller 120 has changed, the CPU 110B returns from the suspend mode to the normal mode (S208).
In step S208, when returning to the normal mode, the CPU 110B returns each component of the USB control unit 100B from the suspend mode and resumes (S209).

When the CPU 110B restores each component of the USB control unit 100B (S209), the CPU 110B determines whether there is a response from the short-range wireless communication module 300 (S210).
When the CPU 110B determines that there is a response from the short-range wireless communication module 300 (S210 Yes), the CPU 110B ends this processing and continues the communication processing with the short-range wireless communication module 300.
If the CPU 110B determines that there is no response from the short-range wireless communication module 300 (No in S210), the CPU 110B resets the short-range wireless communication module 300 and reconnects (S211).

(Embodiment 3)
FIG. 5 is a flowchart showing a processing procedure from when the USB control unit 100A based on the block configuration of FIG. 1 shifts to the suspend mode until it returns to the normal mode. In the third embodiment (FIG. 5), After the USB controller 120 and the short-range wireless communication module 300 shift to the suspend mode, the power related to the USB processing of the CPU 110A (hereinafter, USB processing power) is turned off.

When the power source of the USB control unit 100A is turned on (S301), the CPU 110A confirms whether there is a suspend transition notification from the MPU 150 (S302).
That is, the CPU 110A waits for a suspend transition notification (No in S302), and when the suspend transition notification is made to the CPU 110A (when the CPU 110A confirms the suspend transition notification) (S302 Yes), the CPU 110A includes the USB controller 120 and the near field wireless communication. Command (control) the communication module 300 to shift to the suspend mode (S303).

When the USB controller 120 and the short-range wireless communication module 300 shift to the suspend mode according to the suspend mode shift command (S303) of the CPU 110A (S304), the CPU 110A turns off the USB processing power supply (S305).
When the CPU processing power is turned off (S305), the CPU 110A stores the current processing state (setting) of the USB control unit 100A in the RAM 160 and shifts to the suspend mode (S306).

After the USB control unit 100A shifts to the suspend mode, if the short-range wireless communication module 300 is accessed from, for example, an IC card or a smartphone, the short-range wireless communication module 300 sends a remote wakeup event to the USB control unit 100A. Issue (send remote wakeup signal).
When the USB controller 120 detects the remote wake-up signal transmitted to the USB control unit 100A by the short-range wireless communication module 300 (S307 Yes), the USB controller 120 returns from the suspend mode to the normal mode and transmits a status signal to the MPU 150 (S308). ).

  When the MPU 150 receives the status signal from the USB controller 120 and detects that the state of the USB controller 120 has changed, the MPU 150 triggers the CPU 110A to return the state of the USB control unit 100A from the suspend mode to the normal mode. A signal is transmitted (S309).

When the CPU 110A receives the return trigger signal from the MPU 150, the CPU 110A returns from the suspend mode to the normal mode (S310).
When returning to the normal mode (S310), the CPU 110A turns on the USB processing power supply (S311).
When the USB processing power is turned on (S311), the CPU 110A restores each component of the USB control unit 100A from the suspend mode and resumes (S312).

When the CPU 110A restores each component of the USB control unit 100A (S312), the CPU 110A determines whether there is a response from the short-range wireless communication module 300 (S313).
When determining that there is a response from the short-range wireless communication module 300 (S313 Yes), the CPU 110A ends this processing and continues the communication processing with the short-range wireless communication module 300.
If the CPU 110A determines that there is no response from the short-range wireless communication module 300 (No in S313), the CPU 110A resets the short-range wireless communication module 300 and reconnects (S314).

(Embodiment 4)
FIG. 6 is a flowchart showing a processing procedure from when the USB control unit 100B based on the block configuration of FIG. 3 shifts to the suspend mode to return to the normal mode. In the fourth embodiment (FIG. 6), After the USB controller 120 and the short-range wireless communication module 300 shift to the suspend mode, the USB processing power of the CPU 110B is turned off.
When the power source of the USB control unit 100B is turned on (S401) and then the USB control unit 100B enters an idle state, the CPU 110B determines whether or not the idle state continues for a predetermined time or more (S402).

  When the CPU 110B waits until the idle state of the USB control unit 100B continues for a predetermined time or longer (No in S402) and determines that the idle state continues for a predetermined time or longer (S402 Yes), the CPU 110B determines that the USB controller 120 And the short-range wireless communication module 300 are instructed (controlled) to shift to the suspend mode (S403).

When the USB controller 120 and the short-range wireless communication module 300 shift to the suspend mode according to the suspend mode shift command (S403) of the CPU 110B (S404), the CPU 110B turns off the USB processing power supply (S405).
When the CPU processing power is turned off (S405), the CPU 110B stores the current processing state (setting) of the USB control unit 100B in the RAM 160, and shifts to the suspend mode (S406).

After the USB control unit 100B shifts to the suspend mode, if the short-range wireless communication module 300 is accessed from, for example, an IC card or a smartphone, the short-range wireless communication module 300 sends a remote wakeup event to the USB control unit 100B. Issue (that is, send a remote wakeup signal).
When the USB controller 120 detects the remote wake-up signal transmitted to the USB control unit 100B by the short-range wireless communication module 300 (S407 Yes), the USB controller 120 returns from the suspend mode to the normal mode and transmits a status signal to the CPU 110B (S408). ).

When the CPU 110B receives the status signal from the USB controller 120 and detects that the state of the USB controller 120 has changed, the CPU 110B returns from the suspend mode to the normal mode (S409).
When returning to the normal mode (S409), the CPU 110B turns on the USB processing power supply (S410).
When the USB processing power supply is turned on (S410), the CPU 110B restores each component of the USB control unit 100B from the suspend mode and resumes (S411).

When the CPU 110B restores each component of the USB control unit 100B (S411), the CPU 110B determines whether there is a response from the short-range wireless communication module 300 (S412).
If the CPU 110B determines that there is a response from the short-range wireless communication module 300 (S412 Yes), the CPU 110B ends this processing and continues the communication processing with the short-range wireless communication module 300.
If the CPU 110B determines that there is no response from the short-range wireless communication module 300 (No in S412), the CPU 110B resets the short-range wireless communication module 300 and reconnects (S413).

As described above, according to the electronic device according to the embodiment of the present invention, even if the CPU of the electronic device does not have a function corresponding to the remote wakeup, the electronic device can be returned from the suspend mode by the remote wakeup. Can do.
That is, when the USB controller detects a remote wake-up signal from the USB device, it returns from the suspend mode to the normal mode, and sends a status signal indicating the normal mode to the MPU or CPU, thereby returning the USB host from the suspend mode. Can be made. As described above, by providing the USB controller with a function corresponding to the remote wake-up request, it is possible to reduce the load on the CPU and avoid the deterioration of the processing performance of the electronic device.
Further, the CPU can reduce power consumption by turning off the USB processing power of the CPU after the USB controller and the short-range wireless communication module are shifted to the suspend mode.

  DESCRIPTION OF SYMBOLS 100A ... USB control part, 110A ... CPU, 120 ... USB controller, 130 ... USB connector A, 140 ... USB connector B, 150 ... MPU, 160 ... RAM, 200 ... USB device, 300 ... Near field communication module, 400 ... USB memory, 500 ... USB cable.

Japanese Patent Publication No. 2010-111105

Claims (6)

A connection means for connecting a USB device;
A USB controller for controlling communication with the USB device;
A control unit for controlling the USB controller;
An electronic device comprising:
The USB controller is
Remote wakeup detection means for detecting a remote wakeup signal from the USB device;
A state returning means for returning the power state from the power saving state to the normal power state when a remote wakeup signal is detected by the remote wakeup detecting means;
Have
The control unit is
An electronic device comprising: first state transition means for transitioning the power state from the power saving state to the normal power state based on a change in the power state of the USB controller. The electronic device according to claim 1,
An electronic apparatus, wherein the USB controller includes a state signal output unit that outputs a state signal indicating that the USB controller is in a power saving state or a normal power state. In the electronic device according to claim 1 or 2,
Based on a change in the power state of the USB controller, an auxiliary control unit that generates a trigger signal related to state transition and transmits the trigger signal to the control unit;
The control unit is
An electronic apparatus comprising: a second state transition unit that transitions a power state from a power saving state to a normal power state based on the trigger signal transmitted from the auxiliary control unit. The electronic device according to any one of claims 1 to 3,
An electronic device that controls the control unit to reconnect to the USB device when returning from a power saving state to a normal power state. The electronic device according to any one of claims 1 to 4,
An electronic device that controls the USB processing power to be turned off before the control unit transitions from a normal power state to a power saving state. A return control method from a power saving state in an electronic device comprising: a connection unit that connects a USB device; a USB controller that controls communication with the USB device; and a control unit that controls the USB controller,
A remote wakeup detection step of detecting a remote wakeup signal from the USB device;
A state returning step of returning the power state from the power saving state to the normal power state when a remote wakeup signal is detected in the remote wakeup detecting step;
A state transition step of transitioning the power state from the power saving state to the normal power state based on a change in the power state of the USB controller in the state return step;
Control method for returning from power saving state in electronic device having

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